JP2999826B2 - Supporting elements for fixing flat plate-like building elements to sloping roofs - Google Patents

Abstract

The invention concerns a bearing element (10, 110) for securing a flat panel-shaped unit (40, 140), in particular a photovoltaic unit, to a sloping roof. The bearing element (10, 110) can be fixed to the roof substructure when laid along the crest-gutter line. To produce a bearing element (10, 110) which will allow the unit (40, 140) to be built into a roof covering consisting of small roofing panels or to be incorporated into an existing roof covering without adaptation, it is proposed that the bearing element should be provided with a stay (12) to brace an adjacent (in the crest direction) bearing element (110) lying in the same line of slope at a height above the surface of the overlying panel-shaped unit (40) so as to allow longitudinal displacement.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention tilts a flat plate-like building element, in particular a solar cell element (photovoltaic element), which is laid in a ridge-eave-direction and can be fixed to a roof undercarriage. The present invention relates to a support element for fixing to a roof.

Such a supporting element is known, for example, from DE-A-9409453.9. This document describes a solar cell module arranged so as to overlap like a scale in the vertical direction of a roof. In the following, the ridge-eave-line is referred to as the vertical direction, and the direction parallel to the ridge or eave is referred to as the horizontal direction. Hollow shaped bodies laid in the ridge-eave-direction are provided as support elements. The end of the hollow molded body on the ridge side rests on Komai on the roof base, and the end on the eaves side rests on a wood slide laid parallel to and adjacent to Komai. The wood slide protrudes from the upper edge of Komai by approximately the thickness of the solar cell module. Since the wood slide has a concave portion extending along the vertical center line on its upper surface, when it is arranged at the edges of two solar cell modules that abut each other,
It works to drain water that enters the gap. In the case of this device, additional wood slides must be laid in parallel to Komai and additional windproof hooks surrounding the eaves edge of the solar cell module are required for fixing There is a disadvantage that it is.

The problem underlying the present invention is that, based on the dimensions of the supporting element, it is possible to replace a small number of commercially available roofing panels, so that this building element can be integrated into a roof consisting of small roofing panels. The object of the present invention is to provide a support element for fixing a flat plate-like building element, in particular a solar cell element, to a sloping roof, which can be retrofitted into an already-roofed roof without any adaptation work. .

This object is achieved according to the invention in that the support element is provided with a stay, which is arranged along the same inclined line and adjoins the adjacent support element in the ridge direction above the surface of the plate-like building element resting on the support element. The problem is solved by supporting vertically slidably at the height position.

In order to lay the first building element, at least two support elements are required, arranged in rows parallel to the eave and along mutually parallel lines extending in the ridge-eave-direction. The ridge end of the lowermost support element of the line is
While fixed to the first ebb, the eave-side end overlaps the eaves-direction adjacent roofing plate and is secured to the eave-side second ebb by, for example, a windproof hook. Subsequently, the first building element is mounted on the upper surface of the lower support element. The support element near the ridge following the same line is connected to the stay of the lower support element in the area of its eaves-side end portion and is mounted on the ridge side in a third small dance on the ridge side. In this case, the support element near the ridge is supported at a height above the top surface of the first building element, so that it does not abut against the first building element to accommodate each small dance interval. It can be slid in the eaves direction.

When the supporting element near the ridge slides, its end on the ridge side is fixed on the one hand to the third small dance, and on the other hand the end on the eave side overlaps with the first plate-like building element on the ridge side. To be positioned. Thus, the overlapping eave end portion of the support element near the ridge prevents the first building element from rising from the lower support element.

For a solar cell module 38 cm long and 120 cm wide, for example, the lateral spacing between rows of support elements parallel to the eaves is about 60 cm. When laying a plurality of architectural elements between a ridge and an eave, the plurality of support elements can be arranged along an inclined line.

The length of the support element is longer than the length of the building element, and the building element is longer than the maximum covering length of the adjacent shingle.

The stays transmitting the load from the leg-side end of the overlapping support element to the coated support element should be very stable when placed on top of the support element in the area of the ridge-side end part. It can be formed. This end protrudes from the ridge side edge of the building element.

If the stay is formed as a separate part, the support element can be manufactured as a stamped sheet metal part.
The stay can be formed, for example, as a bent platform.
In this case, the ends of the legs are fixedly connected to the support element.

When the upper end portion of the stay is formed as a connecting element, no additional wind-resistant holding part is required. This connecting element can be slidably connected in a longitudinal direction to a corresponding connecting part of the supporting element near the ridge to be supported, thereby preventing the supporting element of the ridge force from floating.

If the stay can be fixed to the support element with the locking connection element, it is very easy to standardize the support element with the stay.

A shape-complementary and longitudinally slidable connection between the stay and the support element near the ridge may be provided, for example, in that the support element has a longitudinal slit at least in the area of its end on the eaves side and the stay is T-shaped This is achieved by providing the projections. The T-shaped protrusion of the stay is insertable into the support element by a longitudinal slit in the support element near the adjacent ridge. This longitudinally slidable connection prevents the lifting of the support elements near the ridge, but is a non-fixed bearing in the vertical direction, so that changes in the spacing of small dances are always compensated. .

A low-cost implementation of the support element is possible if the support element is formed as a thin-walled shaped body, in particular a hollow shaped body. The support element is preferably formed as a C-shaped body with an open lower side over most of its length.

When the height of the upper surface of the support element is approximately the same as the height position of the draining fold of the roofing plate adjacent to the roof substructure horizontally, and adjacent to the draining fold of the roofing plate Since the edge of the building element to be overlapped with the draining bent part overlaps and can be laid, and the edge of the building element adjacent to the covering bent part of the roofing plate can be laid against the covering bent part, Is extremely easy to assemble.

Plate-like building elements, such as solar modules, are very advantageous because they can be incorporated into sloping roofs covered with commercial flat roofing slabs of concrete or clay. A flat roofing slab made of concrete is usually 42cm long, 33cm wide and 2.2cm high
It is. The roofing board has a covering width of 30 cm and a covering length of 31-34 cm depending on the roof slope. Since the height of the draining fold is 1.2 cm above the lower edge, a solar cell module having a thickness of about 1 cm can be laid closely on the upper surface of the roofing plate.

If a receiving part surrounding the plate-like building element in a hook shape is provided at the end on the eaves side, the module can be inserted and replaced without tools. The base of the receiving part, which is formed in a substantially U-shaped configuration, is preferably higher than the thickness of the building element inserted into this receiving part. Thereby, even if the support element supporting two identical building elements is distorted, the torsional force does not act on the building element. The intermediate chamber may be filled with an elastic or plastically deformable intermediate layer.

The module can be slid towards the ridge onto the support element stays during assembly, and the spacing between the base of the eave-side end receiving section and the ridge-side end stay is If it is longer than the length of the plate-shaped building element by at least the length of the hook of the receiving part, it can be mounted on the support element and subsequently inserted into the receiving part towards the eaves. The removal is performed in reverse order.

If a support for a fixing element for fixing to the roof undercarriage is provided at the ridge-side end of the support element, damage to the underside of the building element may result in a fixing element for windproof fixing of the support element. Is prevented by When a screw is used as the connecting element, it is recommended to provide a recess on the upper side of the support element for supporting the screw head.

Protrusions are provided on the underside of the ridge-side end of the support element, and when the protrusions can be hooked on the roof undercarriage, plate-like building elements can be accurately fitted and easily laid. . This projection acts in the same manner as the hooking projection of Komai by adjusting the support element relative to the upper edge of the Komai ridge side in the vertical direction. The eave-side edge of the building element is held by the receiving part of the supporting element. If the distance between the protrusion and the base of the housing is equal to the distance between the hooking protrusion and the eaves end of the adjacent Komai, the present invention is applied irrespective of the interval of Komai and the cover actually provided on the roof. Building elements, in particular the solar cell modules laid by the support elements according to the above, are in the same geometric position as the adjacent Komai.

A preferred embodiment of the present invention is shown in the figures. Next, this embodiment will be described in detail.

1 is a plan view of a support element according to the invention, FIG. 2 is a longitudinal sectional view of the support element of FIG. 1 along the line II-II, and FIG. 3 is a partial cross section of the support element of FIG. 1 along the line III-III. FIG. 4 is a side view of the assembled two support elements.

FIG. 1 shows a support element 10 in which a stainless steel sheet is stamped and the edges are bent. A stay 12 is provided at the ridge-side end of the support element. This stay can bear the same adjacent support element. A depression is provided on the surface of the support element 10 as a bearing 14 for fixing means for fixing to the roof sill. For example, a screw head can be supported in this recess. The support element 10 has a substantially open C
It is formed as a letter-shaped molded body. The C-shaped body has a longitudinal slit 16 on the lower surface. A long hole 18 is provided on the upper surface in the range of the end portion on the eaves side. The fixing means of the underlying support element can be reached through this slot. At the end on the eaves side, a U-shaped accommodation section 20 for building elements is arranged. This receiving part 20 is wider than the C-shaped molding of the support element 10.

FIG. 2 clearly shows the arrangement structure of the stay 12 and the accommodation section 20 in a longitudinal section. The receptacle 20 protrudes from the area of the C-shaped molding of the support element 10. Thereby, the material can be deformed when a large torsional force is generated due to the deflection of the roof sill, thereby avoiding damage to the installed building elements. The bottom of the U-shaped housing 20 is covered with a strip made of an elastic material. The stay 12 is formed as a mount made of a bent metal sheet. In this case, the end of the leg is fixed to the ridge-side end of the support element 10. The edge of the bend of the stay 12 extends transversely to the longitudinal axis of the support element 10. A projection 24 below the stay 12
Is shown. This protrusion can be hooked on a small underlay of a roof base like a hooking protrusion of a roofing plate.

FIG. 3 is a partial cross-sectional view of the support element 10 of FIG. 1 taken along the line III-III. The left half of the drawing shows the structure of the receiving portion 20 and the right half of the stay 12 is The structure is shown. At the end on the ridge side, projections 26, 2
8 are protruding. A cutout 30 is provided in the area of the lower edge of the storage section 20. This notch allows the outflow of liquid.

The pedestal-shaped stay 12 has slits 32 and 34 formed on both sides thereof extending from the edge at a small distance from the upper edge. Thus, the upper end of the stay 12 is formed as a T-shaped (toggle-shaped) projection 38 by a simple means. In this case, the material between the slits 32, 34 forms the neck 36 and the wall in the area of the upper edge forms a T-shaped part. Adjacent support elements, which support the same as the support element 10, can be inserted into the slits 32,34. Thus, the neck 36 is complementarily arranged in the longitudinal slit 16 and the T-shaped projection 38 is arranged in the adjacent support element.

FIG. 4 shows a longitudinal section of two flat plate-like building elements 40, 140, which are scaled on support elements 10 or 110. In this case, the support element 110 near the ridge is supported by the adjacent support element 10 at the eaves. The reference numbers indicate the same parts as in FIGS. 1 to 3 and the support elements 110 have the reference numbers increased by 100. As shown in the support element 110, a U-shaped accommodation part is formed at the end on the eaves side. This accommodating portion surrounds the eaves side edge of the placed building element 140 in a claw shape. Each support element 10, 110 rests on its ridge end on a small roof 42 or 142 on the roof base and is fixed to this small dance by fixing elements 44, 144 formed as screws. In the case of the support element 110, for example, a support at the eaves end is shown, which is in principle the same for all support elements.
This end is slidable in the vertical direction by means of a stay 12 and is supported on the ridge-side end of the underlying support element 10.

In this case, the support element 110 near the ridge is supported at a position at least as high as the thickness of the plate-like building element 40.
This allows the support element 110 near the ridge to slide in the eaves direction with respect to the lower support element 10 and the building element 40 resting thereon during assembly. This sliding can take place until the ridge 126 on the ridge side of the support element rests on the side of the ridge near the ridge and its eaves-side end overlaps the lower building element 40. The upper building element 140, which rests on the support element 10 near the ridge, is
It is spaced apart from the lower building element 40.
In this case, the upper support element overlaps the ridge side edge of the lower building element 40.

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Resel Norbert, Germany, D-61440 Oberursel, Danziger Strasse, 6 (58) Fields investigated (Int. Cl. ⁷ , DB name) E04D 1 / 30 603 E04D 1/34

Claims (11)

(57) [Claims] 1. A flat plate-shaped building element (40) laid in a ridge-eave direction and fixable to a roof undercarriage, in particular a support element for fixing a solar cell element to a sloping roof. 1
In (0), the support element (10) is provided with a stay (12) which is arranged along the same inclined line and adjoins the support element (110) in the ridge direction with the support element (1).
A support element characterized in that it is supported vertically slidably at a height above the surface of a plate-like building element (40) to be mounted on 0). 2. The support element according to claim 1, wherein the stay is arranged on the surface of the support element in the area of the ridge end of the support element. 3. The support element according to claim 1, wherein the stay is formed as a separate part. 4. The device according to claim 3, wherein the stay is fixed to a support element provided with a locking connection element.
The described support element. 5. The support element (10) is provided with a longitudinal slit (16) at least in the area of its end on the eaves side,
5. The support element according to claim 1, wherein 2) comprises a T-shaped projection (38). 6. The support element according to claim 1, wherein the support element is formed as a thin-walled molding. 7. The height of the top surface of the support element (10) with respect to the plane of the roof undercarriage is approximately the same as the height position of the draining fold of the roof wiper. ~
A support element according to any one of the preceding claims. 8. The support according to claim 1, wherein a housing (20) surrounding the plate-like building element in a hook shape is provided at an end on the eaves side. element. 9. The distance between the base of the accommodation portion (20) at the eaves end and the stay (12) at the ridge end is at least as long as the length of the hook of the accommodation portion (20). 9. The support element according to claim 8, wherein the support element is longer than the length of the plate-like building element. 10. A support (14) for a securing element (44) for securing a roof undercarriage (42) is provided at the ridge end of the support element (10). A support element according to claim 1. 11. The underside of the ridge side end of the support element (10),
Support element according to any one of the preceding claims, characterized in that projections (26, 28) are provided, which projections allow hooking on the roof undercarriage (42).